I've encountered the following problem which is causing me some trouble :

Let $(M^2,g)$ be a smooth compact Riemannian surface (with constant curvature for instance) and consider a smooth function $u:M\times [0,1) \to \mathbb{R}$ which is a solution of the following PDE :
$\partial_t u(x,t)=A(x,t)\Delta u(x,t)$
where $A$ is a function which is smooth on $M\times [0,1)$ and satisfies :
$C_1|1-t|^\alpha \leq A(x,t)\leq C_2$.

It is not hard to see that $u$ is uniformly bounded with the maximum principle, a simple computation also shows that $\int_M |\nabla u(x,t)|^2dv_g$ decreases with $t$, which gives $L^p$ convergence of $u(.,t)$ as $t$ goes to $1$.

My question is : does $u$ have a continuous extension to $M\times[0,1]$ ?

Any insight or reference on this kind of problem is welcome.

Thanks.

EDIT :

Some further observations :

For the application I have in mind, I would be happy with just a sequence $t_i$ going to $1$ such that $u(.,t_i)$ uniformly converges.

The statement in the previous item is true if we replace $M$ by an interval, thanks the Rellich-Kondrachov compactness theorem, in fact, with $M$ of dimension 2,we are exactly at the critical exponent given by Rellich-Kondrachov Theorem.

The statement is true if $A$ depends only on $t$ (not on $x$), just put $t'=\int_0^tA(\tau)d\tau$ and you get that $u(x,t')$ satisfies the usual heat equation.